JP2021055902A - Air shutter device - Google Patents

Abstract

To suppress the decrease in heat blocking effect of an air curtain when an article passes through the air curtain or when there is a temperature difference between the inside and outside of the air curtain.SOLUTION: A first intermediate air outlet 16b and a second intermediate air outlet 20a, which are included in the intermediate range of an installation height range of a first unit 12 and a second unit 14, are arranged vertically side by side in the same direction. The upper region of the first intermediate air outlet 16b and the lower region of the second intermediate air outlet 20a are configured to eject air in the opposite direction to a vertical surface including a first air outlet 16 and a first air suction port 18 facing each other.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to an air shutter device.

Conventionally, an air shutter device is provided at an entrance / exit of a freezer, a freezing truck, or the like where it is necessary to block the inflow / outflow of heat. When loading and unloading products to be frozen in and out of the freezer, and loading and unloading the cargo of the freezing truck, an air curtain is formed at the entrance and exit by the air shutter device to prevent warm air from flowing into the loading platform and the freezer. In another example, an air shutter device is used so that internal heat does not escape when the product to be painted or the product to be dried enters or exits the entrance / exit of the coating equipment or the drying equipment kept at a temperature higher than the outside air. Patent Documents 1 and 2 disclose an air shutter device used for such an application.

Japanese Patent No. 3897732 Japanese Patent No. 6240591

The air shutter device has a problem that when the article passes through the air curtain, the air flow hits the article and a large turbulent flow is generated, so that the heat blocking effect of the air curtain is lowered. Patent Document 1 does not disclose a means for solving such a problem, especially when the article passes through. Patent Document 2 discloses a means for suppressing the generation of turbulent flow and maintaining the heat blocking effect by partially extinguishing the region where the air flow hits the article when the article passes. However, with the means disclosed in Patent Document 2, even if it is partial, a part of the air curtain disappears, so that the heat blocking effect is unavoidably reduced. Further, in Patent Document 2, when an air curtain is formed by a plurality of circulating streams arranged one above the other, the air streams flowing in opposite directions collide with each other at the boundary of the plurality of circulating streams to cause turbulence, and the heat of the air curtain is blocked. It may reduce the effect. Further, when there is a temperature difference between the inlet side and the outlet side of the air curtain, the temperature difference may cause a difference in air density to generate an air flow across the air curtain, which may reduce the heat blocking effect of the air curtain.

The present disclosure has been made in view of the above-mentioned problems, and suppresses a decrease in the heat blocking effect of the air curtain when an article passes through the air curtain or when there is a temperature difference between the inside and outside of the air curtain. With the goal.

In order to achieve the above object, the air shutter device according to the present disclosure includes two sets of a first air outlet and a first air suction port facing each other across the space for forming the air curtain, and the first air outlet. And a first unit that forms a first circulation flow through the first air suction port, and a second air outlet and a second air outlet that are provided below the first unit and face each other across the formation space of the air curtain. 2 The installation of the first unit and the second unit including two sets of air suction ports, including the second air outlet and the second unit forming a second circulation flow passing through the second air suction port. The first intermediate air outlet and the second intermediate air outlet included in the intermediate range of the height range are arranged vertically side by side in the same direction, and the upper region of the first intermediate air outlet and the second intermediate air outlet are arranged. The lower region of the intermediate air outlet is configured to eject air in the opposite direction to the vertical plane including the first air outlet and the first air suction port facing each other, and the first intermediate. At least one of the air outlet or the second intermediate air outlet is located between the upper region of the first intermediate air outlet and the lower region of the second intermediate air outlet, and is located in the upper region. Alternatively, it includes an intermediate air ejection region configured to eject air at an angle smaller than the air ejection angle with respect to the vertical surface of the lower region.

According to the air shutter device according to the present disclosure, when an article passes through the air curtain, it is possible to suppress the generation of a large turbulent flow without losing a part of the air curtain, so that the heat blocking effect of the air curtain can be maintained high. .. Further, even when the air shutter device is provided at the boundary between spaces having different temperatures, the heat blocking effect of the air curtain can be kept high. It also has the role of preventing the intrusion of dust and the like.

It is a schematic front view of the air shutter device which concerns on one Embodiment. It is a schematic plan view of the air shutter device which concerns on one Embodiment. It is a schematic plan view of the air shutter device which concerns on one Embodiment. It is a schematic perspective view of the air shutter device which concerns on one Embodiment. It is a front view of the air outlet provided in the intermediate range which concerns on one Embodiment. It is a front view of the air outlet provided in the intermediate range which concerns on one Embodiment. It is an enlarged view of the louver structure in FIG. It is an arrow view along the X-ray line in FIG. It is a front view of the air outlet provided in the intermediate range which concerns on one Embodiment. It is a top view of the air ejection port shown in FIG. It is a front view of the air outlet provided in the intermediate range which concerns on one Embodiment. It is a top view of the air ejection port shown in FIG. It is a schematic plan view of the air shutter device which concerns on one Embodiment. It is a schematic plan view of the air shutter device which concerns on one Embodiment. It is a schematic front view at the time of passing an article of the air shutter device shown in FIG. It is a schematic front view of the air shutter device as a comparative example. It is a schematic front view at the time of passing an article of the air shutter device shown in FIG.

Hereinafter, some embodiments of the present invention will be described with reference to the accompanying drawings. However, the dimensions, materials, shapes, relative arrangements, and the like of the components described as embodiments or shown in the drawings are not intended to limit the scope of the present invention to this, and are merely explanatory examples.
For example, expressions that represent relative or absolute arrangements such as "in a certain direction", "along a certain direction", "parallel", "orthogonal", "center", "concentric" or "coaxial" are exact. Not only does it represent such an arrangement, but it also represents a state of relative displacement with tolerances or angles and distances to the extent that the same function can be obtained.
For example, expressions such as "same", "equal", and "homogeneous" that indicate that things are in the same state not only represent exactly the same state, but also have tolerances or differences to the extent that the same function can be obtained. It shall also represent the existing state.
For example, the expression representing a shape such as a quadrangular shape or a cylindrical shape not only represents a shape such as a quadrangular shape or a cylindrical shape in a geometrically strict sense, but also an uneven portion or chamfering within a range where the same effect can be obtained. The shape including the part and the like shall also be represented.
On the other hand, the expressions "equipped", "equipped", "equipped", "included", or "have" one component are not exclusive expressions that exclude the existence of other components.

FIG. 1 is a schematic front view showing an air shutter device according to an embodiment. The air shutter device 10 is formed in a unit 12 (first unit) that forms an air circulation flow fc1 (first circulation flow) in a part of an air curtain forming space, and an air curtain forming space that is formed below the unit 12. A unit 14 (second unit) that forms an air circulation flow fc2 (second circulation flow) in another region is provided. The unit 12 includes two sets of an air ejection port 16 (first air ejection port) and an air suction port 18 (first air suction port) facing each other with the space for forming the air curtain interposed therebetween. That is, one set is the air outlet 16 (16a) and the air suction port 18 (18a), and the other set is the air outlet 16 (16b) and the air suction port 18 (18b). The circulation flow fc1 is formed by the air flow ejected from the air ejection port 16 (16a, 16b) and sucked into the air suction port 18 (18a, 18b).

Similarly, the unit 14 also includes two sets of an air ejection port 20 (second air ejection port) and an air suction port 22 (second air suction port) facing each other with the air curtain forming space interposed therebetween. That is, one set is the air outlet 20 (20a) and the air suction port 22 (22a), and the other set is the air outlet 20 (20b) and the air suction port 22 (22b). The circulation flow fc2 is formed by the air flow ejected from the air ejection port 20 (20a, 20b) and sucked into the air suction port 22 (22a, 22b). Circulating flows fc1 and fc2 are formed side by side, and the circulating flows fc1 and fc2 form an air curtain. The intermediate air outlet 16 (16b) (first intermediate air outlet) and the intermediate air outlet 20 (20a) (second intermediate air outlet) included in the intermediate range of the installation height ranges of the units 12 and 14 are They are arranged side by side. In FIG. 1, shows a flow direction of air flow arrows, in particular, to eject an air stream ejected from the intermediate air ejection outlet 16 (16b) indicated by symbol A _1, from the middle air jet port 20 (20a) air The flow is indicated by reference numeral A _2.

FIG. 2 is a schematic plan view of the unit 12, FIG. 3 is a schematic plan view of the unit 14, and FIG. 4 is a schematic perspective view of the air shutter device 10 including the units 12 and 14. 5 to 12 show some embodiments of intermediate air outlets 16 (16b) and 20 (20a). As shown in FIGS. 5 to 12, the upper region r1 of the intermediate air outlet 16 (16b) and the lower region r4 of the intermediate air outlet 20 (20a) face each other in the air outlet 16 (16a) and the intermediate air outlet 20 (20a). It is configured to eject air in the opposite direction to the vertical Pv including the air suction port 18 (18a). The air flow formed by the air ejected from the upper region r1 is indicated by reference numeral a1, and the air flow formed by the air ejected from the lower region r4 is indicated by reference numeral a2.

At least one of the intermediate air outlet 16 (16b) or the intermediate air outlet 20 (20a) has an intermediate air ejection region r2 or r3 between the upper region r1 and the lower region r4. _{The air ejection angle (for example, θ 2} and θ ₃ shown in FIG. 8) with respect to the vertical surface Pv of the air ejected from the intermediate air ejection region r2 or r3 is the vertical surface Pv of the air ejected from the upper region r1 or the lower region r4. It is smaller than the air ejection angle (for example, θ ₁ and θ _{4 shown in FIG. 8).} The air flow ejected from the intermediate air ejection region r2 is indicated by reference numeral a3, and the air flow ejected from the intermediate air ejection region r3 is indicated by reference numeral a4.

According to such a configuration, since the formation region of the air curtain is divided into at least two circulating flows fc1 and fc2, the air volume (wind speed) of each circulating flow can be suppressed, thereby suppressing the air volume (wind speed) of each circulating flow. It is possible to suppress an increase in pressure loss and noise when each circulating flow flows through the duct. Further, as shown in FIG. 1, the two circulation streams fc1 and airflow A ₁ adjacent the boundary region R ₁ of fc2 and A ₂ flows in the same direction, the occurrence of turbulent flow can be suppressed in the boundary region R ₁ .. Thereby, the heat blocking effect of the air curtain can be enhanced.

Further, as shown in FIGS. 2 to 4, when spaces S ₁ (first space) and S ₂ (second space) having a temperature difference between the inlet side and the outlet side of the air curtain are formed, the temperature difference is formed. Due to the difference in air density caused by the air, in the air curtain forming region, when not blocked by the air curtain, air flows aw and ac in opposite directions are generated in the upper region and the lower region. In contrast, in the above embodiment, since the air flow a1 and the air flow a2 ejected in opposite directions with respect to the vertical plane Pv, is ejected in the direction of pushing back the air flow aw into the space S ₂ side, and the air flow the ac by jetting the direction of pushing back to the space S ₁ side, it retain heat shielding effect of the air curtain. Further, since the air flow a3 or a4 ejected from the intermediate air ejection region r2 or r3 fills the gap between the air flow a1 and the air flow a2, an air film having a small gap can be formed. Thereby, the heat blocking effect of the air curtain can be enhanced.

In FIGS. 1 to 3, the air flows a1 to a4 provided in the intermediate range and ejected from the intermediate air outlets 16 (16b) and 20 (20a) are shown by solid lines, and the air outlets 16 (16a) other than the intermediate range are shown by solid lines. ) And 20 (20b) are shown by broken lines.

In one embodiment, as shown in FIG. 1, fans 24 (24a, 24b) (first fan) are provided as means for ejecting air from the air outlet 16 (16a) and the intermediate air outlet 16 (16b). ing. Further, fans 26 (26a, 26b) (second fan) are provided as means for ejecting air from the intermediate air ejection port 20 (20a) and the air ejection port 20 (20b). Since the air flow is formed by the fans 24 and 26, the air volume of the air flow forming the air curtain can be easily adjusted by adjusting the rotation speed of these fans.

In one embodiment, the units 12 and 14 are configured by ducts 28 and 30 erected across an air curtain forming region. Fans 24 and 26 are provided in ducts 28 and 30, respectively. In the unit 12, the air flow a5 ejected from the air outlet 16 by the fan 24 (24a) is sucked into the duct 30 from the air suction port 18 (18a), and the air flow sucked into the duct 30 is the fan 24 ( and ejected from the air ejection port 16 (16b) to form an air flow _{a 1} by 24b), is sucked from the air suction port 18 (18b) in the duct 28, again air ejection outlet 16 by a fan 24 (24a) (16a ) To form a circulating flow fc1. Also in unit 14, similarly to the ejection by the fan 26 (26a) from the air ejection outlet 20 (20a) to form an air flow _{A 2,} is sucked from the air suction port 22 (22a) into the duct 28, again fan 26 (26b) forms a circulating flow fc2 that is ejected from the air outlet 20 (20b) and passes through the ducts 28 and 30.

In the above embodiment, the air curtain is formed by two circulating flows fc1 and fc2 arranged in the vertical direction, but three or more circulating flows are arranged side by side in the vertical direction to form the air curtain. May be good.

FIG. 15 shows the behavior of the air flow forming the air curtain when the article G passes through the air curtain in the above embodiment. In the present embodiment, in the intermediate range, the intermediate air outlets 16 (16b) and 20 (20a) are arranged side by side in the same vertical direction in one of the ducts 30, so that the respective air outlets 16 (16b) and 20 (20a) are arranged side by side. _{After the air flows A 1} and A ₂ formed by the air ejected from 20a) in the same direction collide with the article G, they do not stay around the article G and are adjacent to the air suction ports 18 It is sucked into (18a) and 22 (22b), respectively. Therefore, the generation of turbulent flow is suppressed around the article G and the air film is maintained, so that the heat blocking effect of the air curtain does not decrease. The air flows a5 and a6 formed by the air ejected in the same direction from the air outlets 16 (16a) and 20 (20b) formed in the other duct 28 have the same behavior.

FIG. 16 shows an air shutter device 100 as a comparative example. Air shutter device 100, the circulation flow fc1 and circulation flow opposite the direction of air flow in the boundary region _{R 1} and fc2 _{B 1} and _{B 2} are formed. Since the air flows B ₁ and B ₂ collide with each other, a turbulent flow is generated, the air film is not formed well, and a gap is formed in the air film.

FIG. 17 shows the behavior of the air flow forming the air curtain when the article G passes through the air shutter device 100 in the air shutter device 100. The air flow formed by the air ejected from the air outlet 20 (20b) of the unit 14 in the duct 30 hits the article G and returns to the air suction port 22 (22a) of the unit 14. At this time, the clash becomes airflow B ₁ formed by the air blowing out from the air ejection port 16 (16b) and reverse flow (in the drawing × mark). Therefore, the air flow is turbulent here, a gap is generated in the air film, and the heat blocking effect is reduced. Further, in the duct 28, the air sucked from the lowermost portion to the air suction port 22 (22b) is guided upward by the fan 26 (26a) provided in the unit 14 in the duct 28, and the fan 26 (26a). Is ejected from the air outlet 20 (20a). _{Since the air flow B 2} ejected from the air outlet 20 (20a) has a slightly upward vector, the return air flow after the collision also has a slightly upward vector when it hits the article G. _{The air flow B 2} bounced off the unit 14 by the collision is sucked into the air suction port 18 (18b). The air flow B ₂ pumps up the lower air to the upper part, and the lower air ejected from the air outlet 16 (16a) mixes with the upper air, so that the heat blocking effect of the air curtain is reduced. Further, since the air volume from the air outlet 20 (20a) of the fan 26 (26a) to the air suction port 22 (22b) becomes insufficient, the air film of the air curtain is not formed in this portion, and the air from the outside is not formed. Will be sucked in, and the heat blocking efficiency will decrease.

In one embodiment, as shown in FIGS. 5 to 12, the intermediate air outlets 16 (16b) and 20 (20a) are provided with louvers 32 (32a, 32b, 32c) capable of changing the air ejection angle. Then, the louver 32 determines the air ejection angle with respect to the vertical Pv. By using the louver 32, the air ejection angles of the intermediate air ejection ports 16 (16b) and 20 (20a) can be changed to a desired angle with a simple configuration.
In one embodiment, the intermediate air outlets 16 (16b) and 20 (20a) are defined by a casing 38.

FIG. 5 is a front view of the intermediate air outlets 16 (16b) and 20 (20a) provided with the louvers 32 (32a) according to the embodiment. The louver 32 (32a) has a shape extending along the vertical direction and twisted along the longitudinal direction so that the air ejection angle with respect to the vertical Pv changes along the vertical Pv. By forming a twisted shape on one louver 32 (32a) in this way, the air ejection angle with respect to the vertical plane Pv of the intermediate air ejection ports 16 (16b) and 20 (20a) can be determined by using one louver. Since the desired angle can be continuously changed along the longitudinal direction, the configuration of the louver 32 (32a) can be simplified.

FIG. 6 is a front view of the intermediate air outlets 16 (16b) and 20 (20a) provided with the louver 32 (32b) according to the embodiment, and FIG. 7 is an enlarged view of the louver 32 (32b). FIG. 8 is a view taken along the line XX in FIG. 7. The louvers 32 (32b) are arranged in rows along the vertical Pv at the intermediate air outlets 16 (16b) and 20 (20a), respectively, and the air ejection angles with respect to the vertical Pv are independently different from each other. It is composed of a plurality of louver components 34a, 34b, 34c and 34d that can be arranged so as to be. _{The air ejection angles (θ 2} , θ ₃ ) with respect to the vertical Pv of the louver configurations 34b and 34c provided in the intermediate air ejection regions r2 and r3 are the louver configurations provided in the upper region r1 and the lower region r4. It is smaller than the _{air ejection angle (θ 1} , θ ₄ ) with respect to the vertical Pv of the bodies 34a and 34d. In this way, since the air ejection angles of the louver components 34a to 34d can be changed independently, the ejection direction of the air ejected from the intermediate air ejection ports 16 (16b) and 20 (20a) can be changed to a desired direction. It can be easily changed and an air film with few gaps can be formed. Thereby, the heat blocking effect of the air curtain can be enhanced.

In one embodiment, as shown in FIG. 8, in the louver 32 (32c), the louver components 34a to 34d are fixed to the shaft 36 arranged along the vertical direction, and the angles of these louver components with respect to the lead surface Pv. Is set to be _{θ 1} , θ ₂ , θ ₃ , and θ _{4 in} the order of the louver components 34a to 34d _{(θ 2} <θ ₁ , θ ₃ <θ ₄ ).

FIG. 9 is a front view of the intermediate air ejection ports 16 (16b) and 20 (20a) provided with the louver 32 (32c) according to the embodiment, and FIG. 10 is also a plan view. In this embodiment, the intermediate air ejection regions r2 and r3 have slit-shaped outlets 40 (40a, 40b) extending along the horizontal direction. According to this embodiment, the air ejected from the slit-shaped ejection ports 40 (40a, 40b) fills the gap between the air ejected from the upper region r1 and the air ejected from the lower region r4, so that an air film having a small gap is filled. Can be formed. Thereby, the heat blocking effect of the air curtain can be enhanced.

In this embodiment, as shown in FIG. 9, the slit-shaped spout 40 (40a) extends in the direction opposite to the air ejection direction of the upper region r1, and the slit-shaped spout 40 (40b) is below. It extends in the direction opposite to the air ejection direction of the side region r4. As a result, the intermediate air ejection regions r2 and r3 can form a horizontal flow having a width in the lateral direction that closes the gap between the boundary between the upper region r1 and the lower region r4, so that an air film without a gap can be formed.
Further, in this embodiment, as shown in FIG. 10, the air ejection angle of the air flow a1 in the upper region r1 is θ ₅ with respect to the vertical plane Pv, and the air ejection angle of the air flow a2 in the lower region r4 is _{It is θ 6} with respect to the vertical facing Pv, and the air ejection angles of the air streams a3 and a4 formed by the air ejected from the slit-shaped ejection ports 40 (40a, 40b) are close to 0 ° with respect to the vertical facing Pv. Set. In another embodiment, the air ejection angles of the regions r1 to r4 _{are set to be θ 1} , θ ₂ , θ ₃ and θ ₄ in this order as in FIG. According to these embodiments, an air film without gaps can be formed.

11 and 12 are front views and plan views of the intermediate air ejection ports 16 (16b) and 20 (20a) according to still another embodiment. In this embodiment, in the embodiment shown in FIGS. 9 and 10, the slit-shaped outlets 40 (40a, 40b) formed in the intermediate air ejection regions r2 and r3 are eliminated, and instead, the intermediate air ejection regions r2 and r3 are eliminated. A nozzle 42 is provided at the air outlet of the above. The nozzle 42 ejects the air ejected from the intermediate air ejection ports 16 (16b) and 20 (20a) at an angle smaller than the _{air ejection angle θ 5} or θ _{6 with respect to the vertical surface Pv of the upper region r1 or the lower region r4.} It is configured to do. Further, the nozzle 42 is configured so that the flow path of the air flow gradually decreases toward the tip opening. As a result, the flow velocity of the air flow ejected from the tip opening can be increased, and the reachable distance thereof can be extended. Therefore, the heat blocking effect of the air curtain can be enhanced.

In one embodiment, the air flow a3 ejected from the nozzle 42 has an air ejection angle of 0 ° or around 0 ° with respect to the vertical surface Pv, similarly to the slit-shaped ejection ports 40 (40a, 40b).

As shown in FIGS. 5 to 12, in some embodiments, the air injected from the intermediate air outlets 16 (16b) and 20 (20a) is configured to form an air film with few breaks. There is. Thereby, the heat blocking effect of the air curtain can be enhanced.

Next, as shown in FIGS. 2 to 4, the article G is _{transported from one space S 1 (first space) to another space S 2} (second space) whose temperature is different from that of the space S _1. is configured, an air curtain formed by the air shutter device 10 will be described embodiments are formed at the entrance of the space S _2. For example, space S ₁ is a refrigerating (freezing) truck or a building refrigerating (freezing) storage, and space S ₂ is outside air. In another example, the space S ₂ is a painting facility, a drying facility, or the like, and the space S ₁ is the outside air. In the figure, reference numeral w indicates the transport direction of the article G.

As described above, when a space having a temperature difference is formed between the inlet side and the outlet side of the air curtain, when the air curtain formation region is not blocked by the air curtain due to the difference in air density due to the temperature difference, Air flow in opposite directions is generated in the upper region and the lower region. When the air shutter device 10 according to some of the above-described embodiments is applied under such a situation, the air flow a1 formed by the air ejected from the upper region r1 pushes back the air flow generated in the upper region and pushes back the air flow generated in the upper region to the lower side. The air flow a2 formed by the air ejected from the region r4 can push back the air flow generated in the lower region. Further, the air flows a3 and a4 formed by the air ejected from the intermediate air ejection regions r2 and r3 fill the gap between the air flow a1 ejected from the upper region r1 and the air flow a2 ejected from the lower region r4. Can form an air film with less air. Thereby, the heat blocking effect of the air curtain can be enhanced.

For example, as shown in FIGS. 2 to 4, when the temperature of the space S ₂ is higher than the temperature of the space S ₁ (e.g., the space S ₂ is painting equipment, a heating zone for drying facilities, space S ₁ in the case of the outside air), in the formation region of the air curtain, when not blocked by the air curtain, warm air has become low density and expanded in the space S ₂ is warm flow aw is generated directed from the upper area to the space S _1. As a result, the pressure in the space S ₂ is lowered, so that a low-temperature cold airflow ac is generated from the lower region of the _{space S 1 toward the space S 2.} In this situation, in the present embodiment, the air shutter apparatus 10 includes an air from the upper region r1 to the space S ₂ side is injected, configured as air is injected from the lower region r4 into the space S ₁ side .. An airflow a1 from the upper region r1 is formed by the air injected to the space S ₂ side, together with the warm air flow aw is pushed back to the space S ₂ side, the air injected from the lower region r4 into the space S ₁ side by the air flow a2 formed, cold air ac is pushed back into the space _{S 1.} Thereby, the heat blocking effect of the air curtain can be improved.

In one embodiment, in a situation described above, as shown in FIGS. 2 to 4, from the air ejection port 16 which is not included in the intermediate range of the units 12 (16a) to the space S ₂ side with respect to the vertical plane Pv air is injected, air is injected into the space S ₁ side of the vertical plane Pv from the air ejection outlet 20 (20b) that are not included in the intermediate range of the unit 14. Airflow a5 is formed by the air ejected from the air ejection port 16 (16a), warm air flow aw generated in the upper region of the space S ₂ by the air stream a5 is pushed back to the space S ₂ side. The air flow a6 is formed by the air ejected from the air ejection outlet 20 (20b), cooling air ac generated in the lower region of the space S ₁ by the air stream a6 is pushed back to the space S ₁ side. Thereby, the heat blocking effect of the air curtain can be further improved.

13 and 14 show the _{case where the temperature of the space S 2} is lower than the temperature of the space S ₁ (for example, the space S ₁ is a heating zone of the painting equipment, and the space S ₂ is a cooling zone adjacent to the heating zone. There is.) Is shown. FIG. 13 is a schematic plan view of the unit 12, and FIG. 14 is a schematic plan view of the unit 14. The formation region of the air curtain, when not blocked by the air curtain, in the bottom portion of the space S _2, as shown in FIG. 14, the cold air ac showing dense cold air ac toward the space S ₁ (Figure 3 Cold airflow in the opposite direction) is generated. As a result, the pressure in the space S ₂ decreases, and as shown in FIG. 13, the air flow aw from the upper region of the _{space S 1 toward the space S 2} (the air flow in the direction opposite to the warm air flow aw shown in FIG. 2). ) Occurs.

In this situation, in the present embodiment, the air shutter apparatus 10 includes an air from the upper region r1 to the space S ₁ side is injected, configured as air is injected from the lower region r4 into the space S ₂ side .. An airflow a1 from the upper region r1 is formed by the air injected to the space S ₁ side, the air flow aw toward the upper area to the space S ₂ is pushed back into the space S ₁ side. Further, an airflow a2 formed by the air injected from the lower region r4 into the space S ₁ side, dense cold air ac toward the space S ₁ in the lower region is pushed back to the space S ₂ side. Thereby, the heat blocking effect of the air curtain can be improved.

In one embodiment, the above temperature condition of the original, air is injected from the air injection holes 16 that are not included in the intermediate range of the units 12 (16a) to the space S ₁ side of the vertical plane Pv. The air from the air ejection outlet 20 which is not included in the intermediate range of the unit 14 (20b) to the space S ₂ side with respect to the vertical plane Pv is configured to be injected.

According to such a configuration, air flow a5 is formed by the air ejected from the air ejection port 16 (16a), an air flow aw toward the space S ₂ generated in the upper region of the space S ₁ by the air stream a5 is is pushed back to the space _{S 1} side. The air flow a6 is formed by the air ejected from the air ejection outlet 20 (20b), cold air ac toward the space S ₁ generated in the lower region of the space S ₂ by the air stream a6 is pushed into the space S ₂ side Is done. Thereby, the heat blocking effect of the air curtain can be further improved.

In yet another embodiment, three or more continuous work spaces having different temperatures in adjacent spaces are formed, and an air shutter device having the above configuration is provided at the entrance and exit of each work space. Articles are continuously transported through these work spaces, and each work is performed in each work space. The air shutter device provided at the entrance / exit of each work space suppresses the transfer of heat at the entrance / exit of each work space, so that heat loss can be reduced.

The contents described in each of the above embodiments are grasped as follows, for example.

(1) The air shutter device according to one embodiment includes two sets of a first air outlet and a first air suction port that face each other with the air curtain forming space interposed therebetween, and includes the first air outlet and the first air suction port. 1 A first unit that forms a first circulating flow (for example, the circulating flow fc1 shown in FIG. 1) that passes through an air suction port, and a unit that is provided below the first unit and faces each other across a space for forming the air curtain. A second circulation flow (for example, the circulation flow fc2 shown in FIG. 1) is formed by including two sets of a second air ejection port and a second air suction port to pass through the second air ejection port and the second air suction port. A first intermediate air outlet (for example, the intermediate air outlet 16 (16b) shown in FIG. 1) including the second unit and included in the intermediate range of the installation height range of the first unit and the second unit. ) And the second intermediate air outlet (for example, the intermediate air outlet 20 (20a) shown in FIG. 1) are arranged vertically side by side in the same direction, and the upper region of the first intermediate air outlet (for example, FIG. 6) is arranged. The upper region r1) shown in the above and the lower region of the second intermediate air outlet (for example, the lower region r4 shown in FIG. 6) face the first air outlet and the first air suction port. It is configured to eject air in the direction opposite to the vertical surface including, and at least one of the first intermediate air outlet or the second intermediate air outlet is the upper region of the first intermediate air outlet. An intermediate located between the lower region of the second intermediate air outlet and configured to eject air at an angle smaller than the air ejection angle with respect to the vertical surface of the upper region or the lower region. It includes an air ejection region (for example, the intermediate air ejection region r2 or r3 shown in FIG. 6).

According to such a configuration, since the formation region of the air curtain is divided into at least two circulating flows, the air volume (wind speed) of each circulating flow can be suppressed, thereby each circulating flow. Can suppress the increase in pressure loss and noise when flowing in the duct. Further, since the first intermediate air outlet and the second intermediate air outlet included in the intermediate range of the first unit and the second unit are arranged side by side, the air flows adjacent to each other at the boundary between the two circulating flows ( The air flow ejected from the first intermediate air outlet (for example, the air flow A ₁ shown in FIG. 1) and the air flow ejected from the second intermediate air outlet (for example, the air flow A ₂ shown in FIG. 1) are in the same direction. As a result, the generation of turbulent flow can be suppressed, so that the heat blocking effect of the air curtain can be maintained high. Further, since the first intermediate air outlet and the second intermediate air outlet are arranged one above the other. As will be described later, even when the article passes through, the generation of turbulent flow around the article can be suppressed without losing a part of the air curtain, and the heat blocking effect can be maintained high.

Furthermore, space (e.g., FIG. 2 and the space S ₁ and S ₂ shown in FIG. ₃₎ there is a temperature difference between the inlet side and the outlet side of the air curtain when the is formed, the formation area of the air curtain, the air curtain When not shut off, an air flow in opposite directions (for example, warm air flow aw shown in FIG. 2 and cold air flow ac shown in FIG. 3) is generated in the upper region and the lower region due to the difference in air density caused by the temperature difference. On the other hand, according to the above configuration, the air flow ejected from the upper region of the first intermediate air outlet (for example, the air flow a1 shown in FIGS. 2 and 4) and the lower region of the second intermediate air outlet. The ejected air flow (for example, the air flow a2 shown in FIGS. 3 and 4) acts in the direction of pushing back the air flow generated in the upper region and the lower region, respectively. Further, the air flow formed by the air ejected from the intermediate air ejection region between the first intermediate air ejection port and the second intermediate air ejection port (for example, the air flows a3 and a4 shown in FIGS. 5 to 12) is described. Since the gap between the air ejected from the upper region and the air ejected from the lower region is filled, an air film having a small gap can be formed. Thereby, the heat blocking effect of the air curtain can be enhanced.

(2) The air shutter device according to another aspect is the air shutter device according to (1), and each of the first intermediate air outlet and the second intermediate air outlet has the air ejection angle. It is provided with a changeable louver (for example, the louvers 32 (32a, 32b, 32c) shown in FIGS. 5 to 12).

According to such a configuration, the air ejection angles of the first intermediate air outlet and the second intermediate air outlet can be easily and easily changed by the louver.

(3) The air shutter device according to still another aspect is the air shutter device according to (2), and the louver (for example, the louver 32 (32a) shown in FIG. 5) extends along the vertical direction. It is present and has a twisted shape so that the air ejection angle changes along the vertical plane.

According to such a configuration, the air ejection angles of the first air ejection port and the second air suction port can be easily changed by one louver having a twisted shape.

(4) The air shutter device according to still another aspect is the air shutter device according to (2), and the louver (for example, the louver 32 (32b) shown in FIG. 6) is along the vertical plane. It is composed of a plurality of louver components (for example, louver components 34a to 34d shown in FIG. 7) arranged in a row and capable of forming different air ejection angles with respect to the vertical plane, and in the intermediate air ejection region. The air ejection angles (for example, θ _{2 and} θ ₃ shown in FIG. 8) of the provided louver configuration are the upper region of the first intermediate air outlet and the lower region of the second intermediate air outlet. It is smaller than the air ejection angle (for example, θ _{1 and} θ _{4 shown in FIG. 8) of the louver configuration provided in the region.}

According to such a configuration, by independently adjusting the air ejection angles with respect to the vertical planes of the plurality of louver configurations, the ejection directions of the air ejected from the first intermediate air outlet and the second intermediate air outlet can be adjusted. Each louver structure can be changed in a desired direction along the longitudinal direction with respect to the vertical plane, and an air film with few gaps can be formed. Thereby, the heat blocking effect of the air curtain can be enhanced.

(5) The air shutter device according to still another aspect is the air shutter device according to (2), in which the intermediate air ejection region extends along a horizontal direction (for example, FIG. The slit-shaped spout 40 (40a, 40b) shown in 9 is formed.

According to such a configuration, the air ejected from the slit-shaped outlet formed in the intermediate air ejection region fills the gap between the air ejected from the first air outlet and the air ejected from the second air outlet. Therefore, an air film with few gaps can be formed. Thereby, the heat blocking effect of the air curtain can be enhanced.

(6) The air shutter device according to still another aspect is the air shutter device according to (2), and the intermediate air ejection region is the upper region of the first intermediate air ejection port or the second intermediate region. The nozzle (for example, the nozzle 42 shown in FIGS. 11 and 12) is provided so as to eject air at an angle smaller than the air ejection angle with respect to the vertical surface of the lower region of the air ejection port.

According to such a configuration, since the intermediate air ejection region includes the nozzle having the above configuration, the air flow ejected from the upper region of the first intermediate air outlet and the air flow ejected from the lower region of the second intermediate air outlet. The flow velocity of the air flow that fills the space between the two can be increased to increase the reach. Therefore, the heat blocking effect of the air curtain can be enhanced.

(7) The air shutter device according to still another aspect is the air shutter device according to any one of (1) to (6), and the upper region of the first intermediate air ejection port and the intermediate air ejection. The air film with few breaks is formed by the air injected from the region and the lower region of the second intermediate air ejection port.

According to such a configuration, a seamless air film is formed by the air injected from the first intermediate air outlet and the second intermediate air outlet included in the intermediate range, so that the heat blocking effect of the air curtain can be obtained. Can be enhanced.

(8) The air shutter device according to still another aspect is the air shutter device according to any one of (1) to (7), and is a first fan for ejecting air from the first air ejection port. (For example, the fan 24 (24a, 24b) shown in FIG. 1), the second fan for ejecting air from the second air ejection port (for example, the fan 26 (26a, 26b) shown in FIG. 1), and To be equipped with.

According to such a configuration, by adjusting the rotation speeds of the first fan and the second fan, the flow rate of the air flow formed by these fans can be adjusted, and thereby the air volume of the air curtain can be adjusted.

(9) The air shutter device according to still another aspect is the air shutter device according to any one of (1) to (8), in which the article is in the first space (for example, the space shown in FIGS. 2 and 3). The _{air curtain is configured to be transported from S 1} ) to a second space having a temperature different from that of the first space (for example, the space S ₂ shown in FIGS. 2 and 3), and the air curtain is of the second space. It is formed at the entrance.

As described above, when a space having a temperature difference is formed between the inlet side and the outlet side of the air curtain, when the air curtain formation region is not blocked by the air curtain due to the difference in air density due to the temperature difference, Air flow in opposite directions is generated in the upper region and the lower region. On the other hand, according to the air shutter device according to (1), the upper region and the lower portion are formed by the air flow ejected from the upper region of the first intermediate air outlet and the lower region of the second intermediate air outlet, respectively. The airflow generated in the area is pushed back. Further, since the air ejected from the intermediate air ejection region between the upper region and the lower region fills the gap between the air ejected from the upper region and the air ejected from the lower region, an air film having a small gap is formed. Can be formed. Thereby, the heat blocking effect of the air curtain can be enhanced.

(10) The air shutter device according to still another aspect is the air shutter device according to (9), and when the temperature of the second space is higher than the temperature of the first space, the first intermediate air injection is performed. The upper region of the outlet is injected with air toward the second space side with respect to the vertical plane, and the lower region of the second intermediate air outlet is directed toward the first space side with respect to the vertical plane. It is configured to inject air.

When the temperature of the second space is higher than the temperature of the first space, in the region where the air curtain is formed, when not blocked by the air curtain, the hot air expanded in the upper region of the second space flows toward the first space (for example). , The warm air flow a) shown in FIG. 2 is generated. As a result, the pressure in the second space is reduced, so that an air flow (for example, the cold air flow ac shown in FIG. 3) is generated from the lower region of the first space toward the second space. On the other hand, according to the above configuration, the high temperature air flow generated in the upper region is pushed back to the second space side by the air injected from the upper region of the first intermediate air ejection port toward the second space side. Further, the air injected from the lower region of the second intermediate air ejection port toward the first space side pushes the air flow generated in the lower region back to the first space side. Thereby, the heat blocking effect of the air curtain can be improved.

(11) The air shutter device according to still another aspect is the air shutter device according to (10), and the first air outlet of the first unit, which is not included in the intermediate range, is the vertical. Air (air flow a5 shown in FIGS. 2 and 4) is injected toward the surface on the second space side, and the second air outlet of the second unit, which is not included in the intermediate range, is the vertical. Air (air flow a6 shown in FIGS. 3 and 4) is configured to be injected toward the first space side with respect to the surface.

According to such a configuration, the high temperature air flow generated in the upper region of the second space is pushed back to the second space side by the air injected from the first air outlet not included in the intermediate range, and the intermediate range is formed. The low-temperature air flow generated in the lower region of the first space by the air injected from the second air ejection port not included in the first space is pushed back to the first space side. Thereby, the heat blocking effect of the air curtain can be further improved.

(12) The air shutter device according to still another aspect is the air shutter device according to (9), and when the temperature of the second space is lower than the temperature of the first space, the first intermediate air injection is performed. The upper region of the outlet is injected with air toward the first space side with respect to the vertical plane, and the lower region of the second intermediate air outlet is directed toward the second space side with respect to the vertical plane. It is configured to inject air.

When the temperature of the second space is lower than the temperature of the first space, in the region where the air curtain is formed, when not blocked by the air curtain, the high-density low-temperature air flows toward the first space in the lower region of the second space. appear. As a result, the pressure in the second space is reduced, so that an air flow from the upper region of the first space to the second space is generated. On the other hand, according to the above configuration, the low temperature air flow is pushed back to the second space side by the air injected from the lower region of the second intermediate air outlet to the second space side in the lower region, and the upper region. The air injected from the first intermediate air outlet to the first space side pushes the air flow toward the second space back to the first space side. Thereby, the heat blocking effect of the air curtain can be improved.

(13) The air shutter device according to still another aspect is the air shutter device according to (12), and the first air outlet of the first unit, which is not included in the intermediate range, is the vertical. Air is injected toward the first space side with respect to the surface, and the second air ejection port of the second unit, which is not included in the intermediate range, has air toward the second space side with respect to the vertical plane. It is configured to be jetted.

According to such a configuration, the air injected from the first air outlet not included in the intermediate range pushes the air flow generated in the upper region of the first space back to the first space side and also enters the intermediate range. The low-temperature air flow generated in the lower region of the second space is pushed back to the second space side by the air injected from the second air outlet that is not included. Thereby, the heat blocking effect of the air curtain can be further improved.

10 Air shutter device 12 units (1st unit)
14 units (2nd unit)
16 (16a, 16b) Air outlet (first air outlet)
16 (16b) Intermediate air outlet (1st intermediate air outlet)
18 (18a, 18b) Air suction port (first air suction port)
20 (20a, 20b) Air outlet (second air outlet)
20 (20a) Intermediate air outlet (second intermediate air outlet)
22 (22a, 22b) Air suction port (second air suction port)
24 (24a, 24b) fan (first fan)
26 (26a, 26b) fan (second fan)
28, 30 Duct 32 (32a, 32b, 32c) Louver 34a, 34b, 34c, 34d Louver component 36 Shaft 38 Casing 40 (40a, 40b) Slit spout 42 Nozzle A ₁ , A ₂ , B ₁ , B ₂ , A1, a2, a3, a4, a5, a6 Air flow Pv Vertical facing S ₁ space (first space)
S ₂ space (second space)
ac Cold airflow aw Warm airflow fc1 Circulating flow (1st circulating flow)
fc2 circulation flow (second circulation flow)
r ₁ Upper region r ₂ , r ₃ Intermediate air ejection region r ₄ Lower region w Transport direction θ ₁ , θ ₂ , θ ₃ , θ ₄ , θ ₅ , θ ₆ Air ejection angle

Claims (13)

An air shutter device that forms an air curtain.
Two sets of a first air outlet and a first air suction port facing each other across the formation space of the air curtain are included, and a first circulation flow passing through the first air outlet and the first air suction port is formed. The first unit and
The second air outlet and the second air suction port are provided below the first unit and include two sets of a second air outlet and a second air suction port that face each other across the space for forming the air curtain. The second unit that forms the second circulating flow through the mouth,
With
The first intermediate air outlet and the second intermediate air outlet included in the intermediate range of the installation height range of the first unit and the second unit are arranged side by side in the same direction.
The upper region of the first intermediate air outlet and the lower region of the second intermediate air outlet are in opposite directions with respect to the vertical plane including the first air outlet and the first air suction port facing each other. Is configured to blow air into
At least one of the first intermediate air outlet or the second intermediate air outlet is located between the upper region of the first intermediate air outlet and the lower region of the second intermediate air outlet. An air shutter device including an intermediate air ejection region configured to eject air at an angle smaller than the air ejection angle with respect to the vertical plane of the upper region or the lower region. The air shutter device according to claim 1, wherein each of the first intermediate air outlet and the second intermediate air outlet is provided with a louver capable of changing the air ejection angle. The air shutter device according to claim 2, wherein the louver extends along the vertical direction and has a twisted shape so that the air ejection angle changes along the vertical plane. The louvers are arranged in a row along the vertical plane, and are composed of a plurality of louver components capable of forming different air ejection angles with respect to the vertical plane.
The air ejection angle of the louver configuration provided in the intermediate air ejection region is such that the louver provided in the upper region of the first intermediate air outlet and the lower region of the second intermediate air outlet. The air shutter device according to claim 2, which is smaller than the air ejection angle of the component. The air shutter device according to claim 2, wherein the intermediate air ejection region is formed with a slit-shaped outlet extending along the horizontal direction. The intermediate air ejection region ejects air at an angle smaller than the air ejection angle with respect to the vertical surface of the upper region of the first intermediate air outlet or the lower region of the second intermediate air outlet. The air shutter device according to claim 2, further comprising a nozzle configured in the above. The air film with few breaks is formed by the air injected from the upper region of the first intermediate air outlet, the intermediate air ejection region, and the lower region of the second intermediate air outlet. The air shutter device according to any one of claims 1 to 6. A first fan for ejecting air from the first air ejection port and
A second fan for ejecting air from the second air outlet, and
The air shutter device according to any one of claims 1 to 7. Claims 1 to 8 wherein the article is configured to be transported from the first space to a second space having a temperature different from that of the first space, and the air curtain is formed at the entrance of the second space. The air shutter device according to any one of the items. When the temperature of the second space is higher than the temperature of the first space, air is injected toward the second space side of the upper region of the first intermediate air ejection port with respect to the vertical plane, and the second space is said. The air shutter device according to claim 9, wherein the lower region of the intermediate air ejection port is configured to inject air toward the first space side with respect to the vertical plane. The first air outlet of the first unit, which is not included in the intermediate range, is provided with air injected toward the second space side with respect to the vertical plane, and is included in the intermediate range of the second unit. The air shutter device according to claim 10, wherein the second air outlet is configured to inject air toward the first space side with respect to the vertical plane. When the temperature of the second space is lower than the temperature of the first space, air is injected toward the first space side of the upper region of the first intermediate air outlet with respect to the vertical plane, and the second space is ejected. The air shutter device according to claim 9, wherein the lower region of the intermediate air ejection port is configured to inject air toward the second space side with respect to the vertical plane. The first air outlet of the first unit, which is not included in the intermediate range, is provided with air injected toward the first space side with respect to the vertical plane, and is included in the intermediate range of the second unit. The air shutter device according to claim 12, wherein the second air outlet is configured to inject air toward the second space side with respect to the vertical plane.

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